How Do Cancer-Related Mutations Affect the Oligomerisation State of the p53 Tetramerisation Domain?

Tumour suppressor p53 plays a key role in the development of cancer and has therefore been widely studied in recent decades. While it is well known that p53 is biologically active as a tetramer, the tetramerisation mechanism is still not completely understood. p53 is mutated in nearly 50% of cancers, and mutations can alter the oligomeric state of the protein, having an impact on the biological function of the protein and on cell fate decisions. Here, we describe the effects of a number of representative cancer-related mutations on tetramerisation domain (TD) oligomerisation defining a peptide length that permits having a folded and structured domain, thus avoiding the effect of the flanking regions and the net charges at the N- and C-terminus. These peptides have been studied under different experimental conditions. We have applied a variety of techniques, including circular dichroism (CD), native mass spectrometry (MS) and high-field solution NMR. Native MS allows us to detect the native state of complexes maintaining the peptide complexes intact in the gas phase; the secondary and quaternary structures were analysed in solution by NMR, and the oligomeric forms were assigned by diffusion NMR experiments. A significant destabilising effect and a variable monomer population were observed for all the mutants studied.

Structure-based design of a Cortistatin analogue with immunomodulatory activity in models of inflammatory bowel disease.

Ulcerative colitis and Crohn's disease are forms of inflammatory bowel disease whose incidence and prevalence are increasing worldwide. These diseases lead to chronic inflammation of the gastrointestinal tract as a result of an abnormal response of the immune system. Recent studies positioned Cortistatin, which shows low stability in plasma, as a candidate for IBD treatment. Here, using NMR structural information, we design five Cortistatin analogues adopting selected native Cortistatin conformations in solution. One of them, A5, preserves the anti-inflammatory and immunomodulatory activities of Cortistatin in vitro and in mouse models of the disease. Additionally, A5 displays an increased half-life in serum and a unique receptor binding profile, thereby overcoming the limitations of the native Cortistatin as a therapeutic agent. This study provides an efficient approach to the rational design of Cortistatin analogues and opens up new possibilities for the treatment of patients that fail to respond to other therapies.

Somatostatin, an In Vivo Binder to Aß Oligomers, Binds to ßPFOAß(1-42) Tetramers.

Somatostatin (SST14) is strongly related to Alzheimer's disease (AD), as its levels decline during aging, it regulates the proteolytic degradation of the amyloid beta peptide (Aß), and it binds to Aß oligomers in vivo. Recently, the 3D structure of a membrane-associated ß-sheet pore-forming tetramer (ßPFOAß(1-42) tetramer) has been reported. Here, we show that SST14 binds selectively to the ßPFOAß(1-42) tetramer with a KD value of ∼40 µM without binding to monomeric Aß(1-42). Specific NMR chemical shift perturbations, observed during titration of SST14, define a binding site in the ßPFOAß(1-42) tetramer and are in agreement with a 2:1 stoichiometry determined by both native mass spectroscopy and isothermal titration calorimetry. These results enabled us to perform driven docking and model the binding mode for the interaction. The present study provides additional evidence on the relation between SST14 and the amyloid cascade and positions the ßPFOAß(1-42) tetramer as a relevant aggregation form of Aß and as a potential target for AD.

Aß(1-42) tetramer and octamer structures reveal edge conductivity pores as a mechanism for membrane damage.

Formation of amyloid-beta (Aß) oligomer pores in the membrane of neurons has been proposed to explain neurotoxicity in Alzheimer's disease (AD). Here, we present the three-dimensional structure of an Aß oligomer formed in a membrane mimicking environment, namely an Aß(1-42) tetramer, which comprises a six stranded ß-sheet core. The two faces of the ß-sheet core are hydrophobic and surrounded by the membrane-mimicking environment while the edges are hydrophilic and solvent-exposed. By increasing the concentration of Aß(1-42) in the sample, Aß(1-42) octamers are also formed, made by two Aß(1-42) tetramers facing each other forming a ß-sandwich structure. Notably, Aß(1-42) tetramers and octamers inserted into lipid bilayers as well-defined pores. To establish oligomer structure-membrane activity relationships, molecular dynamics simulations were carried out. These studies revealed a mechanism of membrane disruption in which water permeation occurred through lipid-stabilized pores mediated by the hydrophilic residues located on the core ß-sheets edges of the oligomers.

Preparation of a Well-Defined and Stable ß-Barrel Pore-Forming Aß42 Oligomer.

The formation of amyloid-ß peptide (Aß) oligomers at the cellular membrane is considered a crucial process that underlies neurotoxicity in Alzheimer's disease (AD). To obtain structural information on this type of oligomers, we were inspired by membrane protein approaches used to stabilize, characterize, and analyze the function of such proteins. Using these approaches, we developed conditions under which Aß42, the Aß variant most strongly linked to the aetiology of AD, assembles into an oligomer that inserts into lipid bilayers as a well-defined pore and adopts a specific structure with characteristics of a ß-barrel arrangement. We named this oligomer ß-barrel Pore-Forming Aß42 Oligomer (ßPFOAß42). Here, we describe detailed protocols for its preparation and characterization. We expect ßPFOAß42 to be useful in establishing the involvement of membrane-associated Aß oligomers in AD.

Unmanned Aerial Vehicles (UAVs) and Artificial Intelligence Revolutionizing Wildlife Monitoring and Conservation.

Surveying threatened and invasive species to obtain accurate population estimates is an important but challenging task that requires a considerable investment in time and resources. Estimates using existing ground-based monitoring techniques, such as camera traps and surveys performed on foot, are known to be resource intensive, potentially inaccurate and imprecise, and difficult to validate. Recent developments in unmanned aerial vehicles (UAV), artificial intelligence and miniaturized thermal imaging systems represent a new opportunity for wildlife experts to inexpensively survey relatively large areas. The system presented in this paper includes thermal image acquisition as well as a video processing pipeline to perform object detection, classification and tracking of wildlife in forest or open areas. The system is tested on thermal video data from ground based and test flight footage, and is found to be able to detect all the target wildlife located in the surveyed area. The system is flexible in that the user can readily define the types of objects to classify and the object characteristics that should be considered during classification.

Enantiomeric cyclic peptides with different Caco-2 permeability suggest carrier-mediated transport.

Recently, oral absorption of cyclic hexapeptides was improved by N-methylation of their backbone amides. However, the number and position of N-methylations or of solvent exposed NHs did not correlate to intestinal permeability, measured in a Caco-2 model. In this study, we investigate enantiomeric pairs of three polar and two lipophilic peptides to demonstrate the participation of carrier-mediated transporters. As expected, all the enantiomeric peptides exhibited identical lipophilicity (logD7.4) and passive transcellular permeability determined by the parallel artificial membrane permeability assay (PAMPA). However, the enantiomeric polar peptides exhibited different Caco-2 permeability (Papp) in both directions a-b and b-a. The same trend was observed for one of the lipophilic peptide, whereas the second lipophilic enantiomer pair showed identical Caco-2 permeability (within the errors). These findings provide the first evidence for the involvement of carrier-mediated transport for peptides, especially for those of polar nature.

How the substrate D-glutamate drives the catalytic action of Bacillus subtilis glutamate racemase.

Molecular Dynamics simulations with a Molecular Mechanics force field and a quite complete exploration of the QM/MM potential energy surfaces have been performed to study the D-glutamate --> L-glutamate reaction catalyzed by Bacillus subtilis glutamate racemase. The results show that the whole process involves four successive proton transfers that occur in three different steps. The Michaelis complex is already prepared to make the first proton transfer (from Cys74 to Asp10) possible. The second step involves two proton transfers (from the alpha-carbon to Cys74, and from Cys185 to the alpha-carbon), which occurs in a concerted way, although highly asynchronic. Finally, in the third step, the nascent deprotonated Cys185 is protonated by His187. The positively charged ammonium group of the substrate plays a very important key role in the reaction. It accompanies each proton transfer in a concerted and coupled way, but moving itself in the opposite direction from Asp10 to His187. Thus, the catalytic action of Bacillus subtilis glutamate racemase is driven by its own substrate of the reaction, D-glutamate.

New insights into the reaction mechanism catalyzed by the glutamate racemase enzyme: pH titration curves and classical molecular dynamics simulations.

The mechanism of the reactions catalyzed by the pyridoxal-phosphate-independent amino acid racemases and epimerases faces the difficult task of deprotonating a relatively low acidicity proton, the amino acid's alpha-hydrogen, with a relatively poor base, a cysteine. In this work, we propose a mechanism for one of these enzymes, glutamate racemase (MurI), about which many controversies exist, and the roles that its active site residues may play. The titration curves and the pK1/2 values of all of the ionizable residues for different structures leading from reactants to products have been analyzed. From these results a concerted mechanism has been proposed in which the Cys70 residue would deprotonate the alpha-hydrogen of the substrate while, at the same time, being deprotonated by the Asp7 residue. To study the consistency of this mechanism classical molecular dynamics (MD) simulations have been carried out along with pK1/2 calculations on the MD-generated structures.

On the ionization state of the substrate in the active site of glutamate racemase. A QM/MM study about the importance of being zwitterionic.

Computer simulations on a QM/MM potential energy surface have been carried out to gain insights into the catalytic mechanism of glutamate racemase (MurI). Understanding such a mechanism is a challenging task from the chemical point of view because it involves the deprotonation of a low acidic proton by a relatively weak base to give a carbanionic intermediate. First, we have examined the dependency of the kinetics and thermodynamics of the racemization process catalyzed by MurI on the ionization state of the substrate (glutamate) main chain. Second, we have employed an energy decomposition procedure to study the medium effect on the enzyme-substrate electrostatic and polarization interactions along the reaction. Importantly, the present theoretical results quantitatively support the mechanistic proposal by Rios et al. [J. Am. Chem. Soc. 2000, 122, 9373-9385] for the PLP-independent amino acid racemases.

A Molecular Dynamics Simulation of the Binding Modes of d-Glutamate and d-Glutamine to Glutamate Racemase.

Classical molecular dynamics simulations of the d-Gln/Aquifex pyrophilus MurI and d-Glu/Aquifex pyrophilus MurI complexes have been carried out. Since the active site of the enzyme contains many charged and polar residues, several binding modes are possible. Thus, three very different stable conformations of the substrate analogue d-Gln have been found, and at least three binding modes are possible for the substrate d-Glu. These qualitative results give an explanation for the apparent disagreement between the d-Gln bound MurI X-ray crystal structure and the expected position and orientation of the substrate d-Glu in order to make it possible the assumed Cα deprotonation (by Cys70)/reprotonation (by Cys178) racemization mechanism.